chapter 16 lecture-1

Chapter 16

Respiratory Physiology

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Respiration

• Includes:– Ventilation (breathing)– Gas exchange between

blood and lungs and between blood and tissues

– Oxygen utilization by tissues to make ATP

• Ventilation and gas exchange in lungs = external respiration

• Oxygen utilization and gas exchange in tissues = internal respiration

Respiratory Structures

• Air travels down the nasal cavity

Pharynx Larynx

Trachea

Right and left primary bronchi

Respiratory Structures

Secondary bronchi

Tertiary bronchi (more branching)

Terminal bronchioles

Respiratory zone (respiratory bronchioles

Terminal alveolar sacs

Functions of Conducting Zone

• Transports air to the lungs

• Warms, humidifies, filters, and cleans the air– Mucus traps small particles, and cilia move it

away from the lungs.

• Voice production in the larynx as air passes over the vocal folds

Gas Exchange in Lungs

• Occurs via diffusion

• O2 concentration is higher in the lungs than in the blood, so O2 diffuses into blood.

• CO2 concentration in the blood is higher than in the lungs, so CO2 diffuses out of blood.

Alveoli

• Air sacs in the lungs where gas exchange occurs

• 300 million of them– Provide large surface

area (760 square feet) to increase diffusion rate

Alveolar Cells

• Type I: 95−97% total surface area where gas exchange occurs

• Type II: secrete pulmonary surfactant and reabsorb sodium and water, preventing fluid buildup

• Macrophages: remove pathogens

Thoracic Cavity

• Contains the heart, trachea, esophagus, and thymus within the central mediastinum

• The lungs fill the rest of the cavity.– .

Thoracic Cavity Cross Section

– The parietal pleura lines the thoracic wall.

– The visceral pleura covers the lungs.

– The parietal and visceral pleura are normally pushed together, with a potential space between called the intrapleural space

II. Physical Aspects of Ventilation

Atmospheric Pressure

• Can be measured using a barometer

• At sea level, the atmospheric pressure is 760 mmHg.

Lung Pressures

• Atmospheric pressure: pressure of air outside the body

• Intrapulmonary pressure: pressure in the lungs

• Intrapleural pressure: pressure within the intrapleural space (between parietal and visceral pleura)

• Transpulmonary pressue: Pressure difference between intrapulmonary and intraplueral pressures

Ventilation

• Air moves from higher to lower pressure.

– Pressure differences between the two ends of the conducting zone occur due to changing lung volumes.

– Compliance, elasticity, and surface tension are important physical properties of the lungs.

Pressure Differences When Breathing

• Inhalation: Intrapulmonary pressure is lower than atmospheric pressure.– Pressure below that of the atmosphere is called

subatmospheric or negative pressure• Exhalation: Intrapulmonary pressure is greater than

atmospheric pressure.

Why Lungs stay inflated?

• Intrapleural pressure is always lower than intrapulmonary and atmospheric pressures in both inhalation and exhalation

– Keeps the lungs against the thoracic wall

Boyle’s Law• States that the pressure of a gas

is inversely proportional to its volume– P = 1/V– An increase in lung volume

during inspiration decreases intrapulmonary pressure to subatmospheric levels.

• Air goes in.– A decrease in lung volume

during exhalation increases intrapulmonary pressure above atmospheric levels.

• Air goes out.

III. Mechanics of Breathing

Breathing

• Also called pulmonary ventilation– Inspiration: breathe in– Expiration: breathe out

• Accomplished by changing thoracic cavity/ lung volume

Muscles Involved in Breathing

• Diaphragm most important.– Contracts in inspiration– Relaxes in expiration

• Inspiration: external intercostals

• Expiration: internal intercostals, abs

Mechanisms of Breathing• Inspiration: Volume of thoracic cavity (and lungs) increases

vertically when diaphragm contracts (flattens) and horizontally when parasternal and external intercostals raise the ribs.

Mechanisms of Breathing• Expiration: Volume of thoracic cavity (and lungs) decreases

vertically when diaphragm relaxes (dome) and horizontally when internal intercostals lower the ribs in forced expiration.

Normal vs. Forced Breathing

anim0073-rm_breathing.rm

Lung Compliance

• Is how easily lungs can expand when stretched.

• Defined as the change in lung volume per change in transpulmonary pressure:

ΔV/ΔP

• Reduced by infiltration of connective tissue proteins in pulmonary fibrosis

Elasticity

• Lungs return to initial size after being stretched.

– Lungs have lots of elastin fibers.

– Because the lungs are stuck to the thoracic wall, they are always under elastic tension.

Surface Tension

• Resists distension

• Exerted by fluid secreted in the alveoli

• Raises the pressure of the alveolar air as it acts to collapse the alveolus

Law of Laplace

• Pressure is directly proportional to surface tension and inversely proportional to radius of alveolus.

– Small alveoli would be at greater risk of collapse without surfactant.

Surfactant• Secreted by type II

alveolar cells• Consists of hydrophobic

protein and phospholipids

• Reduces surface tension between water molecules

• More concentrated in smaller alveoli

• Prevents collapse

Surfactant

• Production begins late in fetal life, so premature babies may be born with a high risk for alveolar collapse called respiratory distress syndrome (RDS).

Pulmonary Function Tests

• Spirometry: Subject breathes into and out of a device that records volume and frequency of air movement on a spirogram.

• Measures lung volumes and capacities

• Can diagnose restrictive and disruptive lung disorders

IV. Gas Exchange in the Lungs

Dalton’s Law

• The total pressure of a gas mixture is equal to the sum of the pressures of each gas in it.

• Partial pressure: the pressure of an individual gas; can be measured by multiplying the % of that gas by the total pressure– O2 makes up 21% of the

atmosphere, so partial pressure of O2 = 760 X 20% = 159 mmHg.

Total Pressure

• Nitrogen makes up 78% of the atmosphere, O2 21%, and CO2 1%.

Pdry = PN2 + PO2

+ PCO2 = 760 mmHg

• When air gets to our lungs, it is humid, so the calculation changes to:

Pwet = PN2 + PO2

+ PCO2 + PH2O= 760 mmHg

Partial Pressure

• Addition of water vapor also takes away from the total atmospheric pressure when calculating partial pressure O2.

Relationship Between Alveoli and Capillaries

Role of Gas Exchange

• In the alveoli, the percentage of oxygen decreases and CO2 increases, changing the partial pressure of each.

Partial Pressure in Blood

• Alveoli and blood capillaries quickly reach equilibrium for O2 and CO2.

– This helps maximize the amount of gas dissolved in fluid.

– Henry’s Law predicts this.

Henry’s Law

• The amount of gas that can dissolve in liquid depends on:– Solubility of the gas in the liquid

(constant)– Temperature of the fluid (more

gas can dissolve in cold liquid); doesn’t change for blood

– Partial pressure of the gases, the determining factor

Blood Gas Measurement

• Uses an oxygen electrode

• Only measures oxygen dissolved in the blood plasma. It will not measure oxygen in red blood cells.

• It does provide a good measurement of lung function.

If partial pressure oxygen in blood is more than 5 mmHg below that of lungs, gas exchange is impaired.

Partial Pressure Oxygen

• Changes with altitude and location

Partial Pressure of Gas in Blood

anim0077-rm_respiration.rm

VI. Hemoglobin and Oxygen Transport

Oxygen Content of Blood• In 100 ml of blood

there is a total of 20ml of O2

•

• Very little of O2 is dissolved (0.3 ml/100 ml)

• Most 02 in blood is bound to Hb inside RBCs as oxyhemoglobin

• Hb greatly increases 02 carrying capacity of blood

Hemoglobin

• Most of the oxygen in blood is bound to hemoglobin.– 4 polypeptide

globins and 4 iron-containing hemes

– Each hemoglobin can carry 4 molecules O2.

– 248 million hemoglobin/RBC

anim0079-rm_hemoglobin.rm

Forms of Hemoglobin

• Oxyhemoglobin/reduced hemoglobin: Iron is in reduced form (Fe2+) and can bind with O2.

• Carbaminohemoglobin: Hemoglobin bound to CO2; Normal

• Methemoglobin: Oxidized iron (Fe3+) can’t bind to O2.

– Abnormal; some drugs cause this.

• Carboxyhemoglobin: Hemoglobin is bound with carbon monoxide.

• Bond with carbon monoxide is 210 times stronger than bond with oxygen

– So heme can't bind 02

% Oxyhemoglobin Saturation

• % oxyhemoglobin to total hemoglobin

• Measured to assess how well lungs have oxygenated the blood

• Normal is 97%

• Measured with a pulse oximeter or blood– gas machine

Hemoglobin Concentration

• Oxygen-carrying capacity of blood is measured by its hemoglobin concentration.– Anemia: below-normal hemoglobin levels,

normal PO2 but total O2 low in blood

– Polycythemia: above-normal hemoglobin levels; may occur due to high altitudes

• Erythropoietin made in the kidneys stimulates hemoglobin/RBC production when O2 levels are low.

Loading and Unloading

• Loading: when hemoglobin binds to oxygen in the lungs

• Unloading: when oxyhemoglobin drops off oxygen in the tissues

deoxyhemoglobin + O2 oxyhemoglobin

• Direction of reaction depends on – PO2 of the environment

– affinity for O2.

– High PO2 favors loading.

Loading in Lungs

Unloading in Tissues

Oxygen Unloading

• Systemic arteries have a PO2 of 100 mmHg.

– This makes enough oxygen bind to get 97% oxyhemoglobin.

– 20 ml O2/100 ml blood

• Systemic veins have a PO2 of 40 mmHg.

– This makes enough oxygen bind to get 75% oxyhemoglobin.

– 15.5 ml O2/100 ml blood

– 22% oxygen is unloaded in tissues

PO2 and % Oxyhemoglobin

S-shaped or Sigmoidal curve

In steep part of curve, small changes in P02 cause big changes in % saturation or unloading

Oxyhemoglobin Dissociation Curve

Conditions that shift the curve to the right would cause low affinity and more unloading

↑ CO2

↑ [H+] Bohr effect

↑ Temperature ↑ 2,3-DPG Fever

Conditions that shift the curve to the left would cause more affinity and less unloading

2,3-Diphosphoglyceric acid (2,3-DPG) concentration increase in RBCs increases in anemia and high altitude

Oxygen Dissociation Curve

• Oxygen remaining in veins serves as an oxygen reserve.

• Oxygen unloading during exercise is even greater: – 22% at rest– 39% light exercise– 80% heavy exercise

Effect of pH and Temperature on Oxygen Transport

• pH and temperature change the affinity of hemoglobin for O2.

– This ensures that muscles get more O2 when exercising.

– Affinity decreases at lower pH and increases at higher pH = Bohr effect.

– More unloading occurs at lower pH.

– Increased metabolism = more CO2 = lower pH

Factors That Affect O2 Transport

Fetal Hemoglobin

• Adult hemoglobin (hemoglobin A) can bind to 2,3-DPG, but fetal hemoglobin (hemoglobin F) cannot.

– Fetal hemoglobin therefore has a higher affinity for O2 than the mother, so oxygen is transferred to the fetus.

Inherited Hemoglobin Defects

• Sickle-cell anemia: found in 8−11% of African Americans

– The affected person has hemoglobin S with a single amino acid difference.

– Deoxygenated hemoglobin S polymerizes into long fibers, creating a sickle-shaped RBC.

– This hinders flexibility and the ability to pass through small vessels.

Inherited Hemoglobin Defects

Inherited Hemoglobin Defects

• Thalassemia: found mainly in people of Mediterranean heritage– Production of either alpha or beta chains is

defective.– Symptoms are similar to sickle-cell anemia.

• Both inherited hemoglobin defects carry resistance to malaria.

Myoglobin

• Red pigment found in skeletal and cardiac muscles

• Similar to hemoglobin, but with 1 heme, so it can only carry 1 oxygen molecule

– Higher affinity to oxygen; oxygen is only released when PO2 is very low

– Stores oxygen and serves as go-between in transferring oxygen from blood to mitochondria

VII. Carbon Dioxide Transport

Carbon Dioxide in the Blood

• Carried in the blood in three forms:

– Dissolved in plasma

– As carbaminohemoglobin attached to an amino acid in hemoglobin

– As bicarbonate ions

Chloride Shift

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In tissues there are high C02 levels. This causes increased levels of CO2 in RBCs causing the following reaction to shift to the right.

C02 + H2O H2C03 H+ + HC03-

This results in high H+ & HC03-

levels in RBCs

H+ is buffered by proteins

HC03- diffuses down

concentration & charge gradient into plasma causing RBC to become more positively (+) charged

So Cl- moves into RBC (chloride shift) to balance the charge

HCO3- acts as a major buffer in

plasma

Reverse Chloride Shift

• In lungs following reaction, C02 + H2O H2C03 H+ + HC03

-, moves to the left as C02 is breathed out

• Binding of 02 to Hb decreases its affinity for H+

– H+ combines with HC03-

& more C02 is formed

• Cl- diffuses down concentration & charge gradient out of RBC (reverse chloride shift)

Fig 16.39

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VIII. Acid- Base Balance of the Blood

Acid-Base Balance in Blood

• Blood pH is maintained within narrow pH range by lungs & kidneys (normal = 7.4)

• Most important buffer in blood is bicarbonate– H20 + C02 H2C03 H+ + HC03

-

– Excess H+ is buffered by HC03-

• Kidney's role is to excrete excess H+ into urine

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Bicarbonate as a Buffer• Buffering cannot continue

forever because bicarbonate will run out.– Kidneys help by

releasing H+ in the urine.

Ventilation and Acid-Base Balance

The normal pH of blood is between 7.35 and 7.45. A major buffer which regulates this pH is HCO3

-. This bicarbonate ion traps H+ if the pH gets too low or releases H+ if the pH is too high, thus buffering the system.

If there is a decrease in [H+ ] (or pH increase), thenH2CO3 H➔ + + HCO3

-

 If there is an increase in [H+ ] (a pH decrease), then

HCO3- + H+ ➔ H2CO3

the bicarbonate ion thus functions as a major buffer in blood

• 2 major classes of acids in body:– A volatile acid can be converted to a gas

• E.g. C02 in bicarbonate buffer system can be breathed out

– H20 + C02 H2C03 H+ + HC03-

– All other acids are nonvolatile & cannot leave blood• E.g. lactic acid, fatty acids, ketone bodies

Acid-Base Balance in Blood continued

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Blood pH: Acidosis

• Acidosis: when blood pH falls below 7.35

– Respiratory acidosis: hypoventilation

– Metabolic acidosis: excessive production of acids, loss of bicarbonate (diarrhea)

Blood pH: Alkalosis

• Alkalosis: when blood pH rises above 7.45– Respiratory alkalosis: hyperventilation– Metabolic alkalosis: inadequate production of

acids or overproduction of bicarbonates, loss of digestive acids from vomiting

Ventilation and Acid-Base Balance

• Ventilation controls the respiratory component of acid-base balance.– Hypoventilation: Ventilation is insufficient to

“blow off” CO2. PCO2 is high, carbonic acid is high, and respiratory acidosis occurs.

– Hyperventilation: Rate of ventilation is faster than CO2 production. Less carbonic acid forms, PCO2 is low, and respiratory alkalosis occurs.

Ventilation and Acid-Base Balance

• Ventilation can compensate for the metabolic component.

– A person with metabolic acidosis will hyperventilate.

– A person with metabolic alkalosis will hypoventilate.

V. Regulation of Breathing

Brain Stem Respiratory Centers

• Automatic breathing is generated by a rhythmicity center in medulla oblongata– Consists of inspiratory

neurons that drive inspiration & expiratory neurons that inhibit inspiratory neurons

• Their activity varies in a reciprocal way & may be due to pacemaker neurons

Insert fig. 16.25

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Brain Stem Respiratory Centers

• Inspiratory neurons stimulate spinal motor neurons that innervate respiratory muscles

• Expiration is passive & occurs when inspiratories are inhibited

Insert fig. 16.25

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Brain Stem Respiratory Centers

• Activities of medullary rhythmicity center is influenced by centers in pons – Apneustic center

promotes inspiration by stimulating inspiratories in medulla

– Pneumotaxic center antagonizes apneustic center, inhibiting inspiration

Insert fig. 16.25

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Chemoreceptors

• Automatic control of breathing is influenced by feedback from chemoreceptors, which monitor pH of fluids in the brain and pH, PCO2 and PO2 of the blood.– Central chemoreceptors in

medulla– Peripheral chemoreceptors

in carotid and aorta arteries

Chemoreceptors

• Aortic body sends feedback to medulla along vagus nerve.

• Carotid body sends feedback to medulla along glossopharyngeal nerve.

Regulation of Ventilation

Effects of pH and PCO2 on

Ventilation• When ventilation is inadequate, CO2 levels

rise and pH falls. carbon dioxide + water = carbonic acid

• In hyperventilation, CO2 levels fall and pH rises.

• Oxygen levels do not change as rapidly because of oxygen reserves in hemoglobin, so O2 levels are not a good index for control of breathing.

Effects of PCO2 on Ventilation

• Ventilation is controlled to maintain constant levels of CO2 in the blood. Oxygen levels naturally follow.

Chemoreceptors in the Medulla

• When increased CO2 in the fluids of the brain decrease pH, this is sensed by chemoreceptors in the medulla, and ventilation is increased.

– Takes longer, but responsible for 70−80% of increased ventilation

Peripheral Chemoreceptors

• Aortic and carotid bodies respond to rise in H+ due to increased CO2 levels.

• Respond much quicker

Effect of Blood PO2 on Ventilation

• Indirectly affects ventilation by affecting chemoreceptor sensitivity to PCO2

– Low blood O2 makes the carotid bodies more sensitive to CO2.

Pulmonary Receptors and Ventilation

• Unmyelinated C fibers: affected by capsaicin; produce rapid shallow breathing when a person breathes in pepper spray

• Receptors that stimulate coughing:– Irritant receptors: in wall of larynx; respond to

smoke, particulates, etc.– Rapidly adapting receptors: in lungs; respond

to excess fluid

Pulmonary Receptors and Ventilation

• Hering-Breuer reflex: stimulated by pulmonary stretch receptors

• Inhibits respiratory centers as inhalation proceeds

• Makes sure you do not inhale too deeply

IX. Effect of Exercise and High Altitude on Respiratory

Function

Ventilation During Exercise• Exercise produces deeper, faster breathing to match

oxygen utilization and CO2 production.

– Called hyperpnea

• Neurogenic and humoral mechanisms control this.

Acclimation to High Altitude• Adjustments must be made to compensate for lower

atmospheric PO2.

– Changes in ventilation– Hemoglobin affinity for oxygen– Total hemoglobin concentration

Changes at High Altitude

Respiratory Adaptations to High Altitude